2024
Mechanistic Differences between Torsemide and Furosemide.
Rao V, Cox Z, Ivey-Miranda J, Neville D, Balkcom N, Moreno-Villagomez J, Ramos-Mastache D, Maulion C, Bellumkonda L, Tang W, Collins S, Velazquez E, Mentz R, Wilson F, Turner J, Wilcox C, Ellison D, Fang J, Testani J. Mechanistic Differences between Torsemide and Furosemide. Journal Of The American Society Of Nephrology 2024 PMID: 39196651, DOI: 10.1681/asn.0000000000000481.Peer-Reviewed Original ResearchTorsemide groupDiuretic doseTubular site of actionHigher diuretic dosesDose of furosemideProportion of dosesOral furosemideSite of actionPrescribed doseNeurohormonal activationMechanistic substudyClinical outcomesPharmacodynamic advantagesKidney dysfunctionPharmacodynamic parametersKidney functionRandomized trialsNatriuresisTubular sitesFurosemideTorsemideDoseTRANSFORM-HFPlasma volumeBody weight
2021
FGF-23 (Fibroblast Growth Factor-23) and Cardiorenal Interactions
Ivey-Miranda JB, Stewart B, Cox ZL, McCallum W, Maulion C, Gleason O, Meegan G, Amatruda JG, Moreno-Villagomez J, Mahoney D, Turner JM, Wilson FP, Estrella MM, Shlipak MG, Rao VS, Testani JM. FGF-23 (Fibroblast Growth Factor-23) and Cardiorenal Interactions. Circulation Heart Failure 2021, 14: e008385. PMID: 34689571, PMCID: PMC8782627, DOI: 10.1161/circheartfailure.121.008385.Peer-Reviewed Original ResearchConceptsFGF-23Cardiorenal interactionsHeart failureDiuretic resistanceSodium avidityNeurohormonal activationMultivariable analysisDistal tubular sodium reabsorptionLoop diuretic doseTubular sodium reabsorptionGlomerular filtration rateCardiorenal dysfunctionDiuretic doseDiuretic treatmentNT-proBNPFractional excretionDiuretic administrationSodium reabsorptionPeak diuresisFiltration rateCare centerUrine samplingAnimal modelsSerum chlorideDisease severity
2020
Empagliflozin in Heart Failure
Griffin M, Rao VS, Ivey-Miranda J, Fleming J, Mahoney D, Maulion C, Suda N, Siwakoti K, Ahmad T, Jacoby D, Riello R, Bellumkonda L, Cox Z, Collins S, Jeon S, Turner JM, Wilson FP, Butler J, Inzucchi SE, Testani JM. Empagliflozin in Heart Failure. Circulation 2020, 142: 1028-1039. PMID: 32410463, PMCID: PMC7521417, DOI: 10.1161/circulationaha.120.045691.Peer-Reviewed Original ResearchConceptsSodium-glucose cotransporter 2 inhibitorsCotransporter 2 inhibitorsNeurohormonal activationHeart failureRenal dysfunctionBlood volumeHeart failure-related outcomesPlacebo-controlled crossover studyType 2 diabetes mellitusProximal tubular siteHeart failure outcomesStable heart failureUrinary glucose excretionUric acid levelsElectrolyte wastingEmpagliflozin monotherapyOral empagliflozinPlacebo periodStudy drugGlucose excretionNatriuretic effectPotassium wastingTubular sitesDiabetes mellitusFractional excretion
2019
FGF-23 and Cardio-Renal Interactions in Heart Failure
Stewart B, Gomez N, Barnett J, Thomas A, Wycallis E, Pattoli M, Struyk G, Fleming J, Shamlian P, Raghavendra P, Mahoney D, Ivey-Miranda J, Griffin M, Rao V, Testani J. FGF-23 and Cardio-Renal Interactions in Heart Failure. Journal Of Cardiac Failure 2019, 25: s23-s24. DOI: 10.1016/j.cardfail.2019.07.545.Peer-Reviewed Original ResearchCardio-renal dysfunctionFGF-23 levelsFGF-23NT-proBNPDiuretic responsivenessIL-6Outpatient heart failure (HF) patientsPlasma FGF-23 levelsFibroblast growth factor 23Adverse left ventricular remodelingCardio-renal interactionsHigher NT-proBNPTotal renin levelsPlasma IL-6Heart failure patientsRenal sodium retentionGrowth factor 23High plasma reninLeft ventricular remodelingInduction of inflammationStrong independent associationResults Higher levelsDiuretic doseNeurohormonal activationPhosphaturic hormone